KR101057545B1 - Electrode holder - Google Patents

Abstract

In the through-hole 4 of the metal container attaching part 6, the substantially ring-shaped sheet part 8 which protrudes from an inner periphery is provided, and is hold | maintained in the through-hole 4 through the insulator 5 made of synthetic resin. On the outer circumference of the electrode shaft 3 to be formed, the sheet portion 8 is spaced apart from the sheet portion 8 on at least one of the inner and outer sides of the electrode shaft 3 in the axial direction with respect to the sheet portion 8. The locking projections 13 and 14 of diameter larger than the hole diameter of were provided.

As a result, for example, the inside of the metal container 2 becomes a high temperature state, the insulator 5 is broken, and the electrode shaft 3 extends from the container attaching part 6 to the outside or inside of the metal container 2. When it is about to protrude, the stop projections 13 and 14 stop with the sheet 8 to prevent the electrode shaft 3 from protruding. In addition, the gap between the electrode shaft 3 and the container mounting portion 6 due to breakage of the insulator 5 is blocked by the locking projections 13 and 14 hanging on the sheet portion 8. Even if the insulator 5 is broken, water leakage of the liquid in the metal container 2 can be suppressed as much as possible.

Description

Electrode Holder {ELECTRODE HOLDER}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an electrode retainer for attaching, in an insulating state, an electrode for detecting a liquid level of a liquid contained in a metal container, an electrical conductivity of a liquid, or the like to the metal container.

Background Art Conventionally, for example, liquid level detection means for knowing the liquid level in a case of a boiler, in a water supply tank, etc., and electrical conductivity detection means for knowing the electrical conductivity of water, etc. in the case of a boiler, The electrode holder is attached to the metal container for detection in communication with the water supply tank in an insulated state, and one side of the power source is connected to the electrode of the electrode holder, and the other side of the power source is energized by being connected to the metal container. On the basis of the conduction state between the electrode of the holder and the metal container, a liquid state such as liquid level or electrical conductivity is detected.

The electrode holder attached to the metal container includes an electrode shaft having one end side as a terminal portion and the other end side as a detection electrode portion, a through hole, and holding the electrode shaft through an insulator made of synthetic resin in the through hole. And a metal container attachment portion, wherein the electrode shaft is attached to the metal container by the container attachment portion, in a state where the electrode shaft penetrates the hole portion of the metal container, and in an electrically insulated state from the metal container by the insulator. Known structures are known (see Japanese Patent Laid-Open No. 2000-46628).

In the electrode holder, for example, when the inside is in a high temperature state such as a case of a boiler, the inside of the metal container communicating with this is also in a high temperature state, and in the metal container of the electrode holder attached to the metal container. The exposed insulator may not withstand high temperatures and may be destroyed.

When the insulator is broken in this way, the electrode shaft held in the container attachment part may come out of the container attachment part and fall in the metal container. In particular, if the inside of the metal container is negative pressure, the metal container may fall so as to be sucked into the metal container, which may damage the metal container. In addition, when the inside is made of high pressure, such as a case of a boiler, the inside of the metal container becomes a high pressure, and the electrode shaft held in the container attaching part comes out of the container attaching part by the breakdown of the insulator and protrudes out of the metal container. Moreover, there exists a possibility that the liquid in a metal container may eject from an empty gap between an electrode shaft and a container attachment part.

In addition, since the insulator is made of metal and the electrode shaft and the container mounting part are made of metal, it is easy to slip between the electrode shaft and the insulator or between the container mounting part and the insulator. When the torsional torque is applied to the electrode shaft or the container attaching part from the difference in the coefficient of linear expansion or the molding shrinkage ratio of the synthetic resin, peeling occurs between the electrode shaft and the insulator or between the container attaching part and the insulator, There is a fear that the liquid in the metal container may leak out of the gap where the liquid is peeled off.

The object of the present invention is to prevent the electrode shaft from protruding outside or inside the metal container even if there is a breakdown of the insulator, and the metal container from the gap between the electrode shaft and the container attachment portion due to the breakdown of the insulator. It is to provide an electrode retainer in which leakage of liquid in the liquid is suppressed as much as possible.

Another object of the present invention is to provide an electrode retainer which prevents the occurrence of peeling between the electrode shaft and the insulator or between the container attaching portion and the insulator and prevents the leakage of liquid in the metal container. .

Another object of the present invention is to provide an electrode retainer which has enhanced heat resistance and water repellency of the insulator and has improved durability and insulation.

The object of the present invention described above is a metal container having an electrode shaft having one end side as a terminal portion and the other end side as a detection electrode portion, and a through hole, and holding the electrode shaft through an insulator made of synthetic resin in the through hole. An electrode holder, wherein the electrode shaft is attached to the metal container in a state where the electrode shaft penetrates the hole portion of the metal container by the container attaching part and is electrically insulated from the metal container by the insulator. In the through hole of the container attachment part, a substantially ring-shaped seat section protruding from the inner circumference wall of the container attachment part formed by the through hole is provided, and on the outer circumference of the electrode shaft, The sheet at a distance from the sheet portion on at least one of an inner side or an outer side of the axial direction of the electrode shaft with respect to the sheet portion. With walking of a larger diameter is the diameter of the stop projection (locking protrusion) Installation is achieved by a sustain electrode, characterized in that.

If comprised in this way, for example, the inside of a metal container will be high temperature, the insulator exposed in the metal container of the said electrode holder will not be able to tolerate high temperature, and the said electrode shaft will be broken out of the metal container from the said container attachment part, When it tries to protrude inside, the said stopper part stops with the said sheet | seat part, and the said electrode shaft can prevent it from protruding outside or inside of a metal container. In addition, since the gap between the electrode shaft and the container mounting portion is blocked by the breakdown of the insulator, the sheet portion and the locking projection are blocked by the stop, so that even if the insulator is broken, the leakage of liquid in the metal container is prevented. We can suppress the best.

The locking projections are provided on both the inner side and the outer side of the electrode shaft in the axial direction with respect to the sheet portion.

In such a configuration, even if the insulator exposed in the metal container of the electrode holder is destroyed, and the electrode shaft tries to protrude from the container attaching part to either the outside or the inside of the metal container, the stopping projection is By interlocking with the sheet portion, the electrode shaft can be prevented from protruding to either the outside or the inside of the metal container.

The rotation stop part is provided in the contact surface of the said electrode shaft and the said insulator, and the rotation stop part is provided in the contact surface of the said container attachment part and the said insulator.

In this configuration, when a torsional torque is applied between the electrode shaft and the insulator or between the insulator and the container attaching portion, the respective rotation stop portions are formed between the electrode shaft and the insulator or the container. By preventing slippage between the attachment portion and the insulator, the separation between the electrode shaft and the insulator or between the container attachment portion and the insulator is prevented, thereby preventing leakage of liquid in the metal container. have.

In the through hole of the container attachment portion and the outer circumference of the electrode shaft, a receiving surface in contact with the moving direction of the moving insulator or at an acute angle to receive the movement of the insulator that expands or contracts in the axial direction of the electrode shaft. The protruding protrusion is provided.

When comprised in this way, the insulator which expands or contracts larger than the said metal electrode shaft and the said container attachment part and moves to an axial direction will be received by the receiving surface of the said processus | protrusion. Since the bottom surface of the projection is a surface which is in contact with the moving direction of the moving insulator at right angles or an acute angle, the bottom surface of the protrusion is in intimate contact with the moving insulator and the bottom surface, and the sealing property between the two is increased. Even if peeling occurs between the shaft and the insulator or between the container attaching portion and the insulator, leakage of the liquid in the metal container can be prevented by the seal by the insulator and the receiving surface.

The insulator is composed of an inner insulating layer that is in contact with the electrode shaft and is coated with an outer insulating layer that covers the outer circumference of the inner insulating layer of the portion exposed in the metal container when attached to the metal container. The inner insulation layer is formed of heat resistant, high pressure resistance, and chemical resistant engineering plastics, and the outer insulation layer is made of a resin having good water repellency.

When comprised in this way, the engineering plastic used as the said inner insulation layer is high in heat resistance, high pressure resistance, and chemical-resistance, and can endure high temperature even if it is high temperature in a metal container. However, the engineering plastics are resins having good water repellency, which are structurally changed at around 150 ° C. (glass fiber temperature is changed) and water repellency is deteriorated and insulation is deteriorated, but the outer insulating layer covering the outer circumference thereof is an example. For example, even when the fluorine-based resin is at a high temperature, the water repellency is not deteriorated, and the insulation of the insulator can be maintained. That is, since the inner insulation layer is made of engineering plastic, the insulator is prevented from being destroyed by high temperature, and the outer insulation layer is made of a resin having good water repellency, so that the water repellency of the insulator is maintained.

The engineering plastic is polyether ether ketone, and the resin having good water repellency is an ethylene fluoro-alkoxy ethylene copolymer.

In such a configuration, the heat resistance of the polyether ether ketone is prevented from destroying the insulator due to the high temperature, and the insulation of the insulator is maintained by the water repellency of the ethylene fluoro-alkoxy ethylene copolymer.

The outer insulating layer is engaged so as not to move in the axial direction of the electrode shaft to the locking groove formed at the end of the container mounting portion, and in the axial direction of the electrode shaft to the locking groove formed on the detection electrode portion of the electrode shaft. It's geared to not move.

In this configuration, movement in the axial direction due to contraction of the outer insulating layer is prevented, and between the outer insulating layer and the end of the container attaching part and between the outer insulating layer and the detection electrode part; The gap between the gaps does not occur, and the insulation of the insulator is maintained.

BRIEF DESCRIPTION OF THE DRAWINGS The longitudinal cross-sectional view which shows an example of the form of the electrode holder which concerns on this invention.

2 is a partial cross-sectional view of the X-X ray of FIG.

In order to demonstrate this invention further in detail, this is demonstrated according to attached drawing.

1 and 2 show an example of the form of an electrode retainer according to the present invention, FIG. 1 is a longitudinal sectional view of the electrode retainer of the present example, and FIG. 2 is a partially omitted cross-sectional view of the X-X line of FIG.

The electrode holder 1 of the present example is attached to the metal container 2, and based on the conduction state of the electrode (to be described later) and the metal container 2, the liquid level of the liquid in the metal container 2, the conductivity, and the like. To detect. The metal container 2 is attached to a casing of a boiler, a water supply tank, etc. in succession, and is used for detecting the liquid level, electrical conductivity, etc. of the liquid in the casing of the boiler or the water supply tank.

The electrode holder 1 has an electrode shaft 3 having one end side as a terminal portion 3a and the other end side as a detection electrode portion 3b, and a through hole 4 and the through hole 4. A metal container attaching portion 6 holding the electrode shaft 3 through an insulator 5 made of synthetic resin, wherein the electrode shaft 3 is a hole 7 of the metal container 2; In this state, the insulator 5 is electrically insulated from the metal container 2 and attached to the metal container 2 at the container attaching part 6.

In the container attachment portion 6, a large diameter hexagonal head portion 6a is formed at the upper portion, and a male screw portion 6b is formed at the lower outer circumference to fit the female screw portion formed in the hole portion 7. have.

The through hole 4 is formed in the axial center of the container attaching part 6, and the inner circumference of the container attaching part 6 formed by the through hole 4 is formed in the through hole 4. A substantially ring-shaped sheet portion 8 protruding from the wall is provided.

In addition, the inner wall of the container attaching portion 6 formed by the through hole 4, that is, the contact surface with the insulator 5 is disposed between the container attaching portion 6 and the insulator 5. When a torsional torque is applied, a rotation stopper 10 for preventing rotation by sliding between the container attaching portion 6 and the insulator 5 is provided. The rotation stopper 10 prevents slipping between the container attaching portion 6 and the insulator 5 or increases the contact resistance between the container attaching portion 6 and the insulator 5. If so, the shape is not particularly limited. In this example, the groove 9 is formed in the sheet surface of the sheet portion 8 protruding in the through hole 4 in a direction intersecting with the axis of the through hole 4. The rotation stop part 10 is used. And the said container attaching part 6 and the said insulator 5 integrate, and the said container attaching part 6 and the insulator 5 are integrated by the said insulator 5 sticking into the said groove | channel 9. Slip in between is prevented.

Further, the inner wall of the container mounting portion 6 formed by the through hole 4, that is, the contact surface with the insulator 5 is expanded or contracted larger than the container mounting portion 6 so as to penetrate the through. In order to receive the movement of the said insulator 5 moving in the axial direction of the hole 4, the projection 12 which has the receiving surface 11 which contact | connects the moving direction of the said insulator 5 orthogonal or acute is provided. It is. In this example, the sheet portion 8 serves as the projection 12, and the sheet surface of the sheet portion 8 constitutes the receiving surface 11. This receiving surface 11 is inclined in contact with the insulator 5 which moves in this example, and an acute angle.

Moreover, in the said electrode shaft 3, it is formed from the metal which has a predetermined length, and has corrosion resistance and heat resistance. One end is used as the terminal portion 3a, and the other end is used as the detection electrode portion 3b. The electrode shaft 3 is covered with the insulator 5, leaving the terminal portion 3a and the detection electrode portion 3b, and insulated by the container attaching portion 6.

On the outer circumference of the electrode shaft 3, a predetermined distance is provided between the sheet portion 8 in the axial direction (the side of the detection electrode portion 3b) and the outer side (the terminal portion 3a side). In addition, the locking projections 13 and 14 of diameter larger than the hole diameter of the said sheet part 8 are provided, respectively.

In the present example, as described above, the locking projections 13 and 14 are arranged in the axial direction with respect to the sheet portion 8 as described above (the detection electrode portion 3b). Although it is provided in the side} and the outer side (the said terminal part 3a side), it is not limited to this. In the case where the inside of the metal container 2 to which the electrode holder 1 of this example is attached is a high pressure, the inner periphery of the said sheet | seat part 8 in the circumferential direction of the said electrode shaft 3 (the detection electrode The locking projection 13 on the side 3b side should just be provided. In the case where the inside of the metal container 2 is under negative pressure, the outside projection of the outer side of the electrode shaft 3 with respect to the sheet portion 8 in the axial direction (the terminal portion 3a side) is provided. 14 should be provided.

In addition, when the torsional torque is applied between the electrode shaft 3 and the insulator 5 to the outer circumference of the electrode shaft 3, that is, the contact surface of the insulator 5, the electrode shaft 3 ), And a rotation stopper 15 for preventing rotation by sliding between the insulator 5 is provided.

This rotation stopper 15 prevents slipping between the electrode shaft 3 and the insulator 5 or increases the contact resistance between the electrode shaft 3 and the insulator 5, The shape is not specifically limited. In this example, a through hole 16 penetrating the electrode shaft 3 in a direction orthogonal to the axial direction is formed, and the through hole 16 is used as the rotation stop section 15. The electrode shaft 3 and the insulator 5 are integrated with each other by injecting the insulator 5 into the through hole 16 so that the electrode shaft 3 and the insulator 5 are separated from each other. Slip is prevented.

In addition, the outer periphery of the electrode shaft 3, that is, the contact surface with the insulator 5, in order to receive the movement of the insulator 5 that expands or contracts larger than the electrode shaft 3 and moves in the axial direction. And a projection 18 having a receiving surface 17 in contact with the moving direction of the moving insulator 5 orthogonal or acute. In this example, each said stopping projection part 13 and 14 also serves as the projection 18, respectively, and each surface orthogonal to the axis center of the said electrode shaft 3 of the said stopping projection part 13 and 14 is received. The back surface 17 is comprised. This receiving surface 17 is formed so as to be in contact with the moving direction of the insulator 5 which moves in this example orthogonally.

In this example, a screw hole 19 is formed in the detection electrode portion 3b of the electrode shaft 3 by opening at the tip, and the detection electrode 20 is screwed into the screw hole 19. The detection electrode portion 3b may constitute the detection electrode 20 although the connection is made.

In the insulator 5, in this example, the inner insulation layer 5a and the electrode retainer 1, which are in contact with and covered with the electrode shaft 3, are attached to the metal container 2. It consists of the outer insulation layer 5b which coat | covers the outer periphery of the inner insulation layer 5a of the part exposed in the said metal container 2 at the time.

The inner insulating layer 5a is made of heat resistant, high pressure resistant, and chemical resistant engineering plastic. As this engineering plastic, polyether ether ketone is preferable. In addition to heat resistance, high pressure resistance, and chemical resistance, polyether ether ketone is excellent in moldability. The outer insulating layer 5b is made of a resin having good water repellency, for example, a fluorine resin. As this fluorine-type resin, the fluorine ethylene fluoro alkoxy ethylene copolymer is preferable.

In addition, in this example, the said outer insulating layer 5b is engaged so that it may not move in the axial direction of the stop groove 21 and the electrode shaft 3 formed in the edge part of the said container attachment part 6. The engagement grooves 22 formed in the detection electrode portion 3b are engaged with each other so as not to move in the axial direction of the electrode shaft 3.

As for the electrode holder 1 comprised as mentioned above, the said sheet part 8 is provided in the through-hole 4 of the said container attachment part 6, and the said outer periphery of the said electrode shaft 3, Since the locking projections 13 and 14 having a diameter larger than the hole diameter of the sheet portion 8 are provided at a distance inside and outside the axial direction of the electrode shaft 3 with respect to the sheet portion 8, For example, the inside of the metal container 2 to which the electrode holder 1 is attached becomes a high temperature state, and the insulator 5 exposed in the metal container 2 of the electrode holder 1 has a high temperature. When the electrode shaft 3 tries to protrude from the container attaching part 6 to the outside or the inside of the metal container 2, the stop protrusion 13 or the stop protrusion 14 It stops with the said sheet part 8, and the said electrode shaft 3 is outside the said metal container 2, or It can prevent it from popping out inside.

In addition, the gap between the electrode shaft 3 and the container mounting portion 6 due to breakage of the insulator 5 is such that the sheet portion 8 and the locking projection 13 or the locking projection 14 are separated. Since it is clogged by stopping, even if the said insulator 5 is destroyed, the leakage of the liquid in the said metal container 2 can be suppressed as much as possible.

Further, the rotation stopper 10 is provided on the inner circumferential wall of the container attaching portion 6 formed by the through hole 4, that is, the contact surface with the insulator 5, and the electrode Since the rotation stop 15 is provided on the outer circumference of the shaft 3, that is, on the contact surface with the insulator 5, between the electrode shaft 3 and the insulator 5 or the container attaching part. When a torsional torque is applied between the 6 and the insulator 5, the respective rotation stops 10 and 15 are disposed between the electrode shaft 3 and the insulator 5 or the container attaching part ( 6) and slipping between the insulator 5 is prevented to prevent peeling between the electrode shaft 3 and the insulator 5 or between the container attaching part 6 and the insulator 5. Therefore, leakage of the liquid in the said metal container 2 can be prevented.

Further, the inner circumferential wall of the container attaching portion 6 formed by the through hole 4, that is, the contact surface with the insulator 5, expands or contracts larger than the container attaching portion 6 so as to have an axial direction. In order to receive the movement of the insulator 5 moving in the direction, the projection 12 having a receiving surface 11 in contact with the moving direction of the moving insulator 5 orthogonal or acute is provided, and the electrode shaft ( In order to receive the movement of the insulator 5 moving in the axial direction on the outer periphery of 3), that is, the contact surface with the insulator 5, the electrode shaft 3 is expanded or contracted larger than the electrode shaft 3. Since the projection 18 which has the receiving surface 17 which is in contact with the moving direction orthogonal or acute angle of the () is provided, the insulator 5 and the said receiving surface 11 and 17 which move by expansion or contraction are closely connected, respectively. In contact, the sealing property between them becomes high, and the said electrode shaft 3 and the said insulator 5 are Even if peeling occurs between the container attaching portion 6 and the insulator 5, the metal container 2 is sealed by the insulator 5 and the receiving surfaces 11 and 17. The leakage of the liquid in the inside can be prevented.

In addition, the insulator 5 includes the inner container layer 5a that is in contact with and covered with the electrode shaft 3 and the metal container when the electrode holder 1 is attached to the metal container 2. (2) It consists of the said outer insulation layer 5b which coat | covers the outer periphery of the inner insulation layer 5a of the part exposed in the inside, The said inner insulation layer 5a is heat resistant, high pressure resistance, And chemically resistant engineering plastics, and the outer insulating layer 5b is formed of a fluorine resin. The engineering plastic to be the inner insulating layer 5a has high heat resistance, high pressure resistance, and chemical resistance, and can withstand high temperatures even when the inside of the metal container 2 is in a high temperature state. Changes (glass fiber temperature changes), water repellency is lost and insulation deteriorates. However, even if the fluorine-based resin serving as the outer insulating layer 5b covering the outer circumference thereof does not lose water repellency even at high temperature, the insulating property of the insulator 5 can be maintained.

That is, since the inner insulation layer 5a is made of engineering plastic, the insulator 5 is prevented from being destroyed by high temperature, and the outer insulation layer 5b is made of fluorine resin. The water repellency of the insulator 5 is maintained.

In addition, the outer insulating layer 5b is engaged so as not to move in the axial direction of the stop groove 21 and the electrode shaft 3 formed at the end of the container attaching portion 6, and the electrode Since the engaging groove 22 formed in the detection electrode portion 3b of the shaft 3 is engaged so as not to move in the axial direction of the electrode shaft 3, the outer insulating layer 5b expands or contracts. Movement in the axial direction is prevented and between the outer insulating layer 5b and the end of the container attaching portion 6 and between the outer insulating layer 5b and the detection electrode portion 3b. The insulating property of the said insulator 5 is maintained, without creating a gap between and.

Claims (7)

An electrode shaft having one end side as a terminal portion and the other end side as a detection electrode portion, and having a through hole and a metal container attaching portion for holding the electrode shaft through an insulator made of synthetic resin in the through hole. The electrode holder, which is attached to the metal container in a state where the container attachment portion penetrates the hole portion of the metal container and is electrically insulated from the metal container by the insulator, wherein the container attachment portion is In the through-hole, a ring-shaped sheet portion protruding from the inner circumference wall of the container mounting portion formed by the through-hole is provided, and in the outer circumference of the electrode shaft, inward or outward in the axial direction of the electrode shaft with respect to the sheet portion. At least one of the sides, the locking stones of a diameter larger than the hole diameter of the sheet portion at a distance from the sheet portion Sustain electrode group, characterized in that in addition is provided. The electrode retainer according to claim 1, wherein the locking projection is provided on both the inner side and the outer side in the axial direction of the electrode shaft with respect to the sheet portion. The electrode retainer according to claim 1, wherein a rotation stop is provided on a contact surface between the electrode shaft and the insulator, and a rotation stop is provided on a contact surface between the container attaching portion and the insulator. The said movement in any one of Claims 1-3 in order to receive the movement of the said insulator which expands or contracts in the axial direction of the said electrode shaft in the said through hole of the said container attachment part, and the outer periphery of the said electrode shaft. An electrode retainer, characterized in that a projection having a receiving surface in contact with orthogonal or acute angle with a moving direction of an insulator is provided. The said insulator is an inner insulation layer coat | covered in contact with the said electrode shaft, and the inner insulation layer of the part exposed in the said metal container when attached to the said metal container. An outer insulating layer covering an outer circumference of the inner insulating layer, wherein the inner insulating layer is formed of heat resistant, high pressure resistant, and chemical resistant engineering plastic, and the outer insulating layer is formed of a resin having good water repellency. An electrode holder, characterized in that. The electrode retainer according to claim 5, wherein the engineering plastic is a polyether ether ketone, and the resin having good water repellency is an ethylene fluoro-alkoxy ethylene copolymer. 6. The stopper according to claim 5, wherein the outer insulating layer is engaged with the stop groove formed at the end of the container attachment portion so as not to move in the axial direction of the electrode shaft, and the stop groove formed in the detection electrode portion of the electrode shaft. The electrode holder is engaged so as not to move in the axial direction of the electrode shaft.

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